Mobile ventilation stack assembly

ABSTRACT

The disclosure relates to devices and methods for ventilating enclosed area such as shipping containers or structures erected to temporarily contain cargo items. A central element in such devices and methods is a ventilation stack assembly in which a vertically-oriented stack having an outlet is connected at its other end to a pipe leading to an inlet. A first housing having the dimensions (and preferably the fittings) of a standard shipping container is rigidly connected to the stack and pipes, and the assembly can be physically manipulated as if it were a standard shipping container. Gas (e.g., fumigant) provided to the pipe inlet passes through the pipe and into and through the stack, exiting at the outlet, which can be situated at an altitude whereat gas discharged therefrom is dispersed into the atmosphere at a location and concentration at which displeasure or hazard to humans can be reduced.

CROSS-REFERENCES TO RELATED APPLICATIONS

This application is entitled to priority to U.S. provisional patentapplication No. 62/393,803, which was filed on 13 Sep. 2016.

BACKGROUND OF THE DISCLOSURE

The invention relates generally to the fields of shipping, logistics,and fumigation.

Long-range transportation of materials is common in the modern economy.Materials produced and packaged in one geographical location arecommonly placed within sealed shipping containers having standardizeddimensions for containment and protection from damage (physical,chemical, or hygienic damage) during shipping. Materials can also betransported in breakbulk form or as bulk cargo (e.g., inside a ship)without the use of shipping containers. Use of shipping containershaving standardized dimensions facilitates use of transport vessels(e.g., ships, railroad cars, aircraft, and trucks) andcontainer-handling machinery (e.g., forklifts, reach stackers, straddlecarriers, and cranes) which accommodate them. An example of suchshipping containers is the common intermodal freight container, which isusually made of steel (optionally including insulation and arefrigeration system) and commonly occurs in either of two standardizedsizes (colloquially referred to as “twenty foot” and “forty foot”containers).

Such shipping containers have the advantage of protecting desired goods(e.g., foodstuffs and manufactured wares) and packing materials (e.g.,wooden pallets, burlap bags, or other containers or supports) fromdamage during shipping. However, the shipping containers also protectundesired materials, such as rodents, insects, molds, fungi, or otherorganisms which can damage or infect the desired goods. In manyinstances, it is not practically possible or economically feasible toexclude all of these organisms from a shipping container or, in the caseof non-containerized cargo, to exclude these organisms from thepackaging and cargo itself, during loading, storage, and/or transport.Furthermore, many of these undesirable organisms are carried on orwithin the cargo and/or packing materials, regardless of the presence orabsence of a shipping container.

Undesired organisms can damage, consume, or degrade materials containedwithin shipping containers. Furthermore, such organisms can cause damageor disease at a location at which the shipping container is opened,packing materials are removed, or goods are unloaded. By way of example,insects not found in the United States which live (or have laid eggs on)wooden pallets holding carco can be transported together with thepallets from a non-U.S. country of origin and debark at a distantlocation upon unloading the cargo, and the insects can infest and/ordamage local wildlife (e.g., trees) at the destination. Insects, molds,fungi, or other organisms can adhere to or survive within goodsthemselves, including in or on individual fruits, for example. It istherefore desirable to kill, inactivate, decrease the numbers of, ordecrease the reproductive ability of (individually and collectively,“treating”) any such organisms.

In view of the harm that can be caused by undesirable organisms presentin cargos being transported around the world, countries, localities,their corresponding government agencies, and/or corporate entities canand have enacted laws, rules, or practices whereby in-coming and/orout-going cargos and/or shipping containers are treated for undesirableorganisms.

Fumigation is a common method of treating organisms within a cargo orshipping container. Fumigation involves introducing a gaseous fumigantwhich is toxic or harmful to the undesired organism(s). Because thefumigant is in gaseous form, it tends to penetrate all spaces within thecargo, any packaging, and or a container which contains these, includingporous materials such as masses of grains or coffee beans. Typically,the fumigant is retained within an enclosed area for a predeterminedminimum period of time, the time being dependent on the identity of thefumigant, the type of undesired organisms that are actually orpotentially present, the temperature, and other variable well known toskilled workers in this field. The enclosed area can be substantiallyany portion of three-dimensional space that contains the item(s) to befumigated, such as a structural building, a structure made from flexible(e.g., plastic) sheets or tarps, a ship, an aircraft fuselage, ashipping container, or a combination of these. The materials used todelimit the enclosed area tend to prevent spread, flow, or diffusion ofthe fumigant from within the enclosed area to nearby spaces (although inpractice many structures delimiting enclosed areas exhibit leaks orother minor release of fumigant from the enclosed area). The fumigant isusually removed prior to further handling of the fumigate item(s), so asto minimize the risk of subsequent human exposure to the fumigant.

Fumigants are selected, at least in part, on their ability to causebiological harm. Some are believed to cause environmental harms as well.Common fumigants include methyl bromide and phosphine gas, for example,both of which can be unpleasant, harmful, or even toxic to humans,depending on the concentration and duration of exposure. Methyl bromidecan be harmful to humans in high concentrations. Moreover, its use hasbeen limited or prohibited in some countries, owing to its possibleidentity as a ‘greenhouse gas’ and international agreements regardingsuch gases. Phosphine gas is likewise harmful in high concentrations,and is considered to have an unpleasant odor at lower concentrations.Other fumigants include nitrochloroform, dichloropropene, methylisocynate, hydrogen cyanide, sulfuryl fluoride, and formaldehyde. Humanexposure to all of these fumigants is undesirable at highconcentrations.

Owing to the unpleasant and/or unhealthful characteristics of fumigants,shipping containers, packaging materials, and/or unpacked goodsundergoing fumigation are typically placed in an opened state within afumigant-resistant structure (i.e., in an enclosed area), such as atarpaulin that is sealed about cargo items or another specializedstructure designed to contain the fumigant. By way of example, atent-like structure can be installed within a warehouse, the structurehaving flexible plastic “walls” which are attached to the roof of thewarehouse and which can be raised or lowered at will. A container or oneor more cargo items can be moved to the area within the walls while thewalls are raised, and the walls can thereafter be lowered to the levelof the floor to form an enclosed area that completely surrounds thecontainer or other items within the lowered plastic walls. If desired, ashipping container can be opened and loaded or unloaded within theenclosed area. Fumigant generated or released within the tent canpermeate the container and its contents or other items placed within theenclosed area, achieving its fumigating effect. Following fumigation,fumigant is released (e.g., to the atmosphere or, if desired, fed to anincinerator before venting the incineration exhaust) and the containercan be sealed with its fumigated contents within it or, if the containeror cargo is being fumigated upon unloading, the container or cargo canbe removed together or separately. Typically, most or substantially allfumigant is removed from the enclosed area prior to handling of thefumigated container or cargo. Significant amounts of fumigant can remainin the enclosed area, within a container, or associated with cargoitems, posing a potential hazard to subsequent handlers and workers.When release of fumigant from the structure is not performed carefully,fumigant concentrations that are hazardous or unpleasant for humans candevelop at or near (e.g., downwind from) the site of release.

A substantial need exists for devices and methods for capturing,diluting, venting and/or dispersing fumigants in concentrations and/orplaces where they are not hazardous or unpleasant for humans. Thepresent disclosure describes such devices and methods.

BRIEF SUMMARY OF THE SEVERAL VIEWS OF THE DRAWINGS

FIG. 1 is a diagram of an embodiment of the ventilation stack assemblydescribed herein, wherein an upwardly-extending stack is fluidlyconnected with two pipes through either or both of which fumigant canpass by way of a ‘T’-shaped connector connecting the stack and thepipes. In this embodiment, the stack and the pipes are connected withina first housing that is made from a twenty foot intermodal freightcontainer that has been modified to permit the stack to pass through theroof thereof and the two pipes to extend through the two smallestopposed faces thereof. The first housing is partially filled withconcrete to stabilize the stack assembly when it rests on a horizontalsurface. Two additional housings (in this embodiment, two additionaltwenty foot intermodal freight containers modified to permit the stackto pass through their floors and tops) are stacked atop the firsthousing and secured thereto. Four guy wires connect the four top cornersof the uppermost housing to a collar that is fastened to the stack abovethe uppermost housing. Sources of fumigant (e.g., the interior of anenclosed area containing a fumigant) can be connected to the open endsof either of the two pipes extending from the ends of the first housing.Application of air pressure to the two pipe openings will cause gaseswithin the pipes and the stack to ascend the housing and emerge from theupper end of the stack, which in this embodiment is situated at analtitude 70 feet above the horizontal surface upon which the stackassembly rests. Exiting gases can be diffused in air currents present atthat altitude.

DETAILED DESCRIPTION

The disclosure relates to devices and methods for capturing and/ordiffusing gases ventilated from enclosed areas which contain goods orcontainers being fumigated. Although the subject matter is describedherein in the context of removing a fumigant used to kill or injureundesired organisms from an enclosed area, it is recognized that thesame subject matter can be used to remove substantially any gaseouscomponent including, by way of example, gases (e.g., ethylene) used toripen or to inhibit ripening of fruit, gaseous combustion products, andinert gases meant merely to displace oxygen or air so as to reduceoxidation. In the context of describing the operation of the devices andmethods described herein, each of these gases (regardless of intendeduse) is referred to as a “fumigant” or merely a “gas” for ease ofdiscussion.

A significant element of the devices and methods described herein is astack assembly, one embodiment of which is illustrated in FIG. 1.

The stack assembly includes a tubular stack that extends substantiallyvertically and is connected to one or more tubular pipes through afitting (preferably a substantially right-angle fitting) such that theinteriors of the stack and the pipe(s) are in fluid communication. Thestack, the pipe, or both are secured to a first housing which has thedimensions of a standard shipping container. The first housing caninclude a ballast to provide weight (and resistance to tipping) to thestack assembly, and the weight of ballast used is preferably at leastabout the weight of the stack, or much greater. The stack assembly caninclude one or more additional housings stacked atop the first housing.Such additional housings, when present, should also have the dimensionsof the a shipping container, preferably the same standard shippingcontainer as the first housing. One or more lines (herein “guy wires”)can connect a fitting (e.g., a collar) secured to the stack to one ormore of the housings, to provide stability (i.e., resistance to movementattributable to gravity or momentum while moving the stack assembly, orresistance to wind pressure while the stack assembly is stationary) tothe stack, relative to the housing(s).

Further details of the portions of the stack assembly are describedbelow.

The Stack

The stack is a hollow, tubular structure that, in operation, will extendgenerally vertically. The purpose of the stack is to facilitateconveyance of gases in a direction from the bottom (i.e., earth-side) ofthe stack toward its top (i.e., sky-ward) side.

The precise shape, length, and material of the stack are not critical,and should be selected to contain gas within its interior duringconveyance during operation as described herein. The stack can be madeof metal or plastic, for example, and should be sufficiently rigid thatit will hold its shape in the presence of the gases expected to beconveyed through it and under the environmental conditions (e.g.,locally prevalent winds, sunlight intensity, and precipitation) in whichit will be used. A wide variety of metal pipes, both smooth andcorrugated are suitable, as are plastic (e.g., PVC) pipes. The stack maybe composed of multiple tubes (e.g., two circular tubular metal pipes),if desired, but this is not preferred. The cross-sectional shape (e.g.,round, square, oval, triangular) is not critical. For ease of supply andconstruction, hollow pipes having a circular cross-section areappropriate.

The stack has an opening (i.e., an outlet) at its upper end and connectswith one or more pipes (described below) at its lower end. A gaseousmaterial, such as fumigant removed from an enclosed area, is received bythe stack at its lower end and, in the presence of greater gas pressureor gas movement at the lower end, the gaseous material is induced tomove upwardly through the stack, venting (i.e., exiting from the stack)at the opening at its upper end.

The length of the stack is not critical, but is selected to vent gas atan altitude above the horizontal surface upon which the assembly stackrests that provides sufficient atmospheric dispersion of the gas thatthe hazard or unpleasantness of the gas to humans is reduced below adesired level (e.g., below the level specified in a regulation or belowa level that is subjectively considered unacceptable to nearbyresidents). Methods for calculating stack heights necessary to produce adesired degree of gas dispersion are known in the art (See, e.g.,Beychok, Fundamentals of Stack Gas Dispersion, 4^(th) ed., 2005, ISBN0-9644588-0-2). Such calculations will depend upon the identity andvolume of the gas(es) being vented, the hazard or unpleasantcharacteristic to be avoided, prevalent local meteorological conditions,local topology and obstacles, for example. For land-based ventilationstacks (e.g., at container-loading and—unloading dockyards), a stackoutlet altitude of at least about 70 feet above the ground surface willnormally suffice in relatively flat terrain. Shorter (e.g., as short as40 feet or less) or taller (e.g., 90-100 feet or more) stacks can alsobe appropriate, depending on the factors described herein. Stack heightcan also be determined empirically, for example by using a selectedstack height for a limited time, measuring gas concentrations (ordetectability, such as odor) nearby, and increasing or decreasing stackheight accordingly. For ship-borne ventilation stacks (e.g., on acontainer vessel), a stack outlet altitude of at least theship's-exhaust outlet will tend to be sufficient.

The internal area of the stack (i.e., the cross-sectional space throughwhich the gas is to flow) is not critical, other than that it should besufficient to convey the anticipated volume of gas that will begenerated in use without requiring specialized or expensive gas-movingequipment. Sizing of exhaust pipe cross-sectional areas such as here iswithin the level of ordinary skill in this field.

The size of the stack and the material from which it constructed willinfluence its weight and the effect of that weight on the overallstability of the stack assembly. For example, a heavier stack will tendto destabilize the stack assembly—an effect that can be counteracted byincluding a greater weight of ballast in the first housing.

The Pipes

The stack assembly includes at least one, preferably two, and possiblymore, pipes which convey a gas to be ventilated from a source of the gasto the stack. The pipes contain the gas during that conveyance. Thus,the precise shape, size, and length of each pipe is not critical, nor isthe material from which it is made.

Like the stack, the material from which each pipe is constructed shouldbe constructed to that it is sufficiently rigid that it retains itsshape during conveyance of gas from its source to the stack, taking intoaccount the chemical and physical nature of the gas to be conveyed.Metal or plastic pipes of substantially any cross-sectional shape willsuffice. For ease of construction and availability of materials,ordinary cylindrical pipes can be used, as can rectangular or deformablematerials commonly used as ductwork in industrial or residentialsettings.

Preferably, each pipe is substantially rigid and extends from itsconnection to the stack at least through (and preferably beyond) a faceof the first housing to an inlet end of the pipe. However, the length ofeach pipe can be selected so that it is contained within the firsthousing; this is important if, for example, the first housing is ashipping container and the pipe extends from its junction with the stackwithin the shipping container toward one of the end-doors of theshipping container and closing of the doors at that end is desirable(e.g., for protection, storage, or shipping of the housing).Alternatively, multiple disassemblable pieces of pipe can be used suchthat, when assembled the portions of the pipe extend from the lower endof the stack beyond the position of the first housing at which end-doorsof a shipping container would normally be present, but such that whendisassembled, the pipe does not extend beyond that position (and,optionally, the disassembled pieces can be stowed within the housing,e.g., for shipping).

The form of the inlet is not critical, and can be any form orconfiguration that will facilitate transfer of gas from an exteriorsource into the interior of the pipe. This arrangement facilitatesconnection of a gas source to the pipe at or near the face of the firsthousing, such that gas from the source will be conveyed into the pipeinlet, through the pipe (and within the housing) to the stack and thenceto the stack outlet. By way of example, the pipe can be a rigidcylindrical pipe which extends about a foot beyond one face of thehousing, as illustrated in FIG. 1. Also as illustrated in FIG. 1, thehousing can have multiple pipes secured to it, each of the pipes fluidlyconnecting to the stack within the housing.

The inlet end of a pipe preferably includes one or more fittings forattaching gas-handling equipment (e.g., rigid or flexible ducts or hosesfor conveying a gas to be vented through the pipe and stack, optionallyusing gas-moving equipment as described herein, such as a gas conveyor).Such fittings permit users of the stack assembly to attach a gas source(e.g., an outlet line leading from a shipping container that isundergoing fumigation or an enclosed area within which goods have beenunloaded from a ship, an aircraft, or shipping container) to the pipeinlet end in order to direct gases from the gas source to the stack. Anyof a wide variety of gas-handling fittings can be used (e.g., snap-fitconnections, frictional connections, flange-to-flange connections withor without a gasket, or screw-type connections), and such fittings arepreferably substantially gas tight, so as to reduce exposure of users togases flowing through the fittings. The inlet end (and any associatedfittings) are preferably situated on the first housing in such a manneras to render the area of the pipe inlet(s) well-ventilated. As shown inFIG. 1, for example, the pipe inlets can be situated at the ends of thefirst housing, extending slightly therefrom, so that any gas which mayescape at the pipe inlet can be removed from the area of escape, ratherthan accumulating (e.g., as might occur if the pipe inlet were withinthe closed space of the first housing).

The interior of each pipe fluidly connects with the interior of thestack at a fitting end of the pipe, so that gas flowing from the openend toward the fitting end of the pipe will pass into the interior ofthe stack after exiting the fitting end of the pipe. The connectionbetween each pipe and the stack is preferably substantially gas-tight,so that substantially all gas flowing through the pipe enters the stack.The exact nature of the connection is not critical. For ease ofconstruction and availability of materials, it can be preferable to usestandard piping connectors (e.g., tubular right-angle or ‘T’-shaped pipeconnectors), and these can be frictionally fit, flange-bolted, orwelded, for example. Flexible, moldable, or welded connections are alsosuitable. As illustrated in FIG. 1, a pair of pipes can be connected tothe stack using a ‘T’-shaped connector having bolted flange-type pipeconnectors fitted about the fitting end of each pipe, the lower end ofthe stack, and each of the three openings of the ‘T’-shaped connector.Because it can be advisable to fully or partly disassemble the stackwhen moving the stack assembly, the stack is preferably disassemblablefrom the pipe(s), either at the lower end of the stack or at anintermediate position between its upper and lower ends (e.g., at aboutthe position at which the stack emerges from the first housing or theuppermost housing).

The pipes will generally be arranged substantially parallel to thesurface upon which the housing rests, meaning generally horizontally fora ventilation stack assembly designed to rest on a flat area of ground.Such an arrangement is not critical, however, so long as the pipesfluidly connect with the stack, preferably within the first housing.

Gas-moving equipment can be associated with, or included within a pipe(e.g., attached at the inlet end of the pipe or between the pipe and thestack) or associated with, or included within the stack (e.g., at thebase of the stack, within the stack, or at the outlet of the stack). Byway of example, simple gas conveyors such as fans or turbines can beinstalled in fluid communication with the interior of a pipe to inducegas movement therethrough. Similarly, gas discharge nozzles (forintroducing gases into a pipe), vacuum orifices (for withdrawing gasesfrom a pipe), or other known equipment for inducing gas flow can beused. The cross-sectional area (e.g., diameter for a hollow cylindricalpipe) of the pipe should be selected to accommodate a desired gas flowfor convenient use. By way of example, when an a maximal expected gashandling rate and gas handling equipment are selected, a pipecross-sectional area can be readily calculated using well-known methods.

In one embodiment, one or more gas conveyors are contained within amanifold having at least one intake and at least one outlet. Themanifold functions to draw gas into its inlet(s) and to expel thedrawn-in gas out from its outlet(s). A manifold having multiple inletsand/or outlets can be equipped with covers or seals to plug unusedinlets or outlets in order to facilitate connection of multiple manifoldinlet(s) to the same or separate enclosed areas containing fumigant,connection of multiple manifold outlet(s) to a single or multiplestacks, or a combination of these. By way of example, a manifold canhave two intakes, each fluidly connected with the interior of adifferent enclosed areas containing fumigant (and the two enclosed areascan contain the same or different fumigants), while being fluidlyconnected through a single outlet with a single stack. Alternatively, amanifold can fluidly connect the interior of a single enclosed area withtwo different stacks, each stack being connected to a different outletof the manifold, and the manifold can be fluidly connected with theenclosed area by way of a single intake manifold or multiple ones.

The First Housing

The first housing serves both as a stabilizing support base upon whichthe ventilation stack assembly rests and to secure at least one of thestack and the pipe(s) (and preferably both the stack and all pipes).Furthermore, the first housing has the dimensions of a standard shippingcontainer (e.g., the size and shape of a common twenty foot intermodalfreight container), which permits it to be manipulated usingstandardized freight container-handling equipment, such as forklifts,reach stackers, straddle carriers, and cranes. Because this equipmentwill often be present at locations at which the ventilation stackassembly is to be used, the ventilation stack assembly can be readilymoved around the location as needed.

The first housing includes at least a frame that has the dimensions of astandard shipping container, and preferably includes the fittings (e.g.,corner twist-lock connectors) typically present on such containers. In apreferred embodiment, the first housing is made from such a container(e.g., one which has been rendered unsuitable for use as a containerowing to puncture of its sides).

The junction(s) of the stack and the pipe or pipes of the ventilationstack assembly is contained within the first housing. The first housingis rigidly connected with at least one of the stack and the pipes whichjoin the stack within it. This rigid connection causes the stack, thepipe(s) and the first housing to be movable as a single rigid unit.Preferably, the first housing is rigidly connected with the stack andalso with each pipe which connects with the stack within the firsthousing. By being rigidly connected with each of these, the rigidity ofthe entire ventilation stack assembly can be increased.

The means by which the first housing is connected with the stack and/orpipe(s) is not critical, and any rigid connection can be use. By way ofexample, the first housing can be welded to the stack where the stackextends through an otherwise-solid wall of the first housing and/or to aframe attached to the housing. Similarly by way of example, the firsthousing can be welded to each pipe where the pipe extends to or throughan otherwise-solid wall of the first housing and/or to a frame attachedto the housing. The first housing can have a frame (e.g., pipes or beamswelded to the structural elements of the first housing, such as to theframe elements of a shipping container) situated therein (whetherrigidly connected to the first housing or not) for supporting the weightof the stack and/or pipes. Whatever the details of the connectionsbetween the first housing and the stack and between the first housingand the pipe(s), the desirable outcome is a rigid, resilient ventilationstack assembly that can be practically moved through manipulation of thefirst housing (and optionally other housings) without damaging theconnections among the stack, the pipes, and the first housing.

When a shipping container is used as the first housing, the end-doors ofthe shipping container can be removed. Alternatively, they can be lefton and operable, so that they can be closed—around the pipe(s) if thedoors are modified to remove the section(s) that would otherwiseinterfere with the pipe, or with the end of the pipe within thecontainer if the pipe is sufficiently short or disassemblable.

Ballast

The first housing preferably (but not necessarily) contains or includesa ballast for providing weight to the first housing and, thereby, to thebase of the ventilation stack assembly.

The identity of the ballast is not critical, and the ballast can bereadily removable or substantially irremovable. By way of example,movable ballast can take the form of a liquid contained by walls of thefirst housing, or of particulate material (sand, gravel, or concreterubble). Movable ballast can be useful for reducing the weight of theventilation stack assembly, such as when it is being moved about alocation or loaded aboard a ship. The movable ballast can be removedprior to such movement and replaced thereafter. By way of example,immovable ballast can take the form of a settable material (e.g., pouredcement or concrete) or an adhered material (e.g., scrap metal welded tothe first housing frame) that is substantially fixedly associated withthe first housing.

The amount of ballast included with the first housing is not criticaland can be readily determined by a skilled artisan in this field.Generally, a greater amount of ballast will result in greater stability(i.e., resistant to tipping) of the ventilation stack assembly, whileless ballast will reduce its weight and improve the ease of transportingthe assembly (especially if the housing is moved with the stackassembled to the pipes).

Additional Housings

One or more additional housings, having the same dimensions as the firsthousing, can be stacked atop (i.e., on the face through which the stackextends of) the first housing. Like the first housing, each additionalhousing can be an actual standardized shipping container, a damaged(i.e., no long suitable for shipping) standardized shipping container,merely the frame of a standardized shipping container, or a framedesigned simply to mimic the size and shape of the frame of astandardized shipping container.

The method or mechanism by which the additional housings are attached tothe first housing are not critical. They can, for example, be weldedtogether or fastened using standard shipping container fasteners,provided that both the first housing and the additional housing bearfittings compatible with such fasteners.

The stack extends through the top and floor (i.e., bottom) faces of eachadditional housing, and the stack can be rigidly attached to eachadditional housing (e.g., welded to a solid face through which itextends or connected to a frame attached to the additional housing) ifdesired.

Each additional housing preferably has the fittings associated with astandardized shipping container, such as the twist-lock connections atits corners. The presence of these fittings permits the ventilationstack assembly to be treated and handled as though it is a stack ofstandardized shipping containers (e.g., picked up and moved fromlocation-to-location about a site).

Like the first housing, each additional housing can both support thestack (the first housing can also support the pipe(s)) and shield thestack from damage from trucks, cranes, shipping containers, or otherobjects which might otherwise incidentally impact the stack while inuse. Substantial physical movement of machinery and shipping containersis common at sites at which shipping containers are manipulated (e.g.,marine terminals, warehouses, and shipping centers). When the stack (andpipe(s)) are contained within a housing (e.g., a modified shippingcontainer), the housing can bear the damage from such potentialcollisions, rather than the stack.

Stack Fitting(s) and Guy Wires

In order to provide additional rigidity to the stack, the stack can haveone or more fittings thereon, and one or more lines can connect thosefittings to portions of the first housing or an additional housing.Rigidification of stacks, poles, and other extended members using suchlines is well known in the art, and substantially any method ofproviding such rigidification can be employed.

By way of example, the fitting can be a perforated collar that isattached (e.g., welded) to the stack about two-thirds of the distancebetween the top surface of the uppermost housing and the outlet of thestack (i.e., the collar being situated nearer the stack). Metal guywires can be tautly secured between the perforations of the collar and,for example, the four corners of the uppermost housing.

The Enclosed Area Containing Fumigant

The stack of the ventilation stack assembly described herein can be usedto safely exhaust fumigant from an enclosed area (e.g., the interior ofa shipping container, the interior of a sealed building, or the interiorof a structure formed, in whole or in part, using flexible plastic offabric sheets) in which the fumigant is present by fluidly connectingthe interior of the stack and the interior of the enclosed area throughthe interior of the pipe. If the density of the fumigant issubstantially less than the density of air (or whatever other gas may bepresent at the stack outlet), then exhaust of the fumigant can beachieved (albeit relatively slowly) by merely permitting air to settleinto the enclosed area and fumigant to rise out of the stack by fluidlyconnecting the two. Similarly, even when the fumigant is about equallydense as air at the stack, simple of diffusion of the fumigant throughthe ventilation stack assembly and out the stack outlet will occur, butgenerally too slowly to be of commercial importance.

The rapidity with which a fumigant is exhausted from an enclosed areacan be substantially increased by inducing convective flow of gas fromthe enclosed area, through the ventilation stack assembly, and out theoutlet of the stack. Convective gas flow can be induced by introductionof gas into the enclosed area, by generation of gas within the enclosedarea, by withdrawal of gas from the stack when it is connected to theenclosed area in a substantially gas-tight manner, or by a combinationof these. Commonly, convective gas flow is induced using gas conveyors,such as fans, turbines, vents, blowers, and other common air-handlingequipment. Such gas conveyors can be used in connection with theventilation stack assembly described herein in conventional ways, andcan be fluidly connected in line with the assembly, the enclosed area,or both. By way of example, a gas conveyor (e.g., a fan or a manifoldcontaining a blower) can fluidly connect the interior of a fumigationcontainer with the interior of a pipe of the assembly. Activation of theconveyor will tend to draw gas from within the enclosed area and impelit into the pipe and thence up the stack and out from the stack outlet.Gas flow can be increased further by venting air or other gas into theinterior of the enclosed area (e.g., by positively injecting gas thereinor by permitting ambient air to flow into the enclosed area through, forexample single-direction vents). A gas conveyor can also be incorporatedwithin the assembly itself, if desired—for example interposed betweenthe stack and a pipe, or at the stack outlet.

The identity and form of the structure(s) used to make the enclosed areaare not critical. Such enclosed areas will generally be closed to theatmosphere (so as to contain fumigant therein) and have one or moreoutlets which can be connected with gas-handling equipment, such as gasconveyors, and one or more vents for admitting ambient (fumigant-free)gas into the enclosed area. By way of example, a standard shippingcontainer can be used to contain a fumigant therein by generatingfumigant within (or injecting fumigant into) the container. If one endof the shipping container is fluidly connected with the stack assemblydescribed herein, fumigant can be withdrawn from the container andvented from the stack outlet; gas throughput can be increased (andfumigant withdrawal speeded) by allowing atmospheric air or another gasto enter the shipping container to replace withdrawn gas (e.g., byopening a door or vent of the shipping container).

In another embodiment of a fumigation container, a dedicated,free-standing building can be constructed, and materials (e.g., cargoitems or opened shipping containers) to be fumigated placed within it.Upon generation or injection of fumigant within the building, thebuilding can sealed from its surroundings to prevent migration offumigant from within the building to those surroundings. The ventilationstack assembly described herein can be connected (if it was notpreviously) to the interior of the building (which, here, is theenclosed area) and fumigant can be vented therefrom at a selected time(e.g., after a fumigation procedure). Air or other gas can be providedto the interior of the building to increase gas flow rates and speedremoval of fumigant. Such gas provision can be effected usingnegative-pressure-activated vents (e.g., slat-type ventilation vents),dedicated gas lines, or in any other manner that will result in gassupply to the interior of the building. Rather than a permanentbuilding, temporary structures can be used, such as tents, sheets orflaps of gas-impermeable plastic, tarpaulins, fabric sheets, or othermaterials can be used to contain a fumigant within an enclosed areadelimited by the temporary structures (optionally, in combination with amore permanent building, as with plastic sheeting extending between theroof and floor of a warehouse) until it can be vented therefrom usingthe ventilation stack assembly described herein. Materials (e.g., fruitor packing materials to be fumigated can be loaded into such temporarystructures or the structures can be built or moved around the materialsto be fumigated.

Using the Ventilation Stack Assembly

The ventilation stack assembly is used by fluidly connecting a source ofa gas to be ventilated (e.g., the interior of an enclosed areacontaining a fumigant) with the interior of at least one pipe of theassembly. Each other pipe is either connected to the same or anothersource of the gas or is closed (e.g., using a valve, a gas-tight seal,or a solid plate). Once this connection is made, the gas is able to flowfrom the enclosed area, through the pipe, into and along the stack, andthence vent at the stack outlet. Flow of gas can be significantlyaccelerated by passing a fluid (e.g., more of the gas, air, or anon-reactive gas such as nitrogen) through this system, such as byintroducing the fluid at the source.

By way of example, fumigation of a shipping container can be performedby fluidly connecting a source of a gaseous fumigant to the interior ofthe shipping container after fluidly connecting the interior of theshipping container to the interior of a pipe of the ventilation stackassembly. As the fumigant gas is passed into the shipping container, itwill exhibit its fumigant effects within the shipping container, andexit the container into the pipe. Once in the pipe, the fumigant gaswill pass through the pipe, through the connection between the pipe andthe stack, up the stack, and ‘out’ the outlet of the stack. If thatoutlet is situated at an altitude of 70 feet above ground, for example,any remaining fumigant gas in the outlet stream will disperse within air70 feet above the ground. This altitude can be selected to avoidunpleasant or hazardous effects of the fumigant gas affecting humans oranimals in the vicinity of the ventilation stack assembly.

After fumigant gas has been passed into and through the enclosed areafor a desired time period, another fluid such as ambient air cancontinue to be passed into and through the enclosed area. This has theeffect of ‘flushing’ or diluting any remaining fumigant gas from theenclosed area, yielding a enclosed area which will exhibit lessunpleasant or hazardous conditions to people subsequently handling orunloading items within the enclosed area than would have been the caseabsent such flushing or dilution.

In another example, an incinerator can be included within the ventilatorstack assembly, in the fluid flow stream including the pipe(s) and thestack, with the incinerator igniting and burning at least a portion ofthe fumigant gas. Such an assembly will reduce the quantity of fumigantgas released to the atmosphere at the stack outlet.

In yet another example, the ventilator stack assembly can have a stackhaving an outlet that connects with a fumigant gas recovery system. Suchan assembly can reduce atmospheric release of the fumigant gas, and canpotentially facilitate recycling of the gas or treatment of the gas(e.g., scrubbing of exhaust streams and/or chemical reaction of thefumigant to render it less hazardous to humans or the environment).

The ventilation stack assembly disclosed herein can be used on land(e.g., at a dockside, railside, or airport facility for preparingshipping containers for loading or for processing unloaded shippingcontainers). Owing to its compactness and compliance with shippingcontainer size parameters, the ventilation stack assembly can be loadedonto, for example, a ship (optionally with the stack removedtemporarily), either for transportation or for use en route.Furthermore, because the housings have the dimensions of standardshipping containers, they can be manipulated (e.g., lifted, moved, ordisassembled) using equipment likely to be already present for otherpurposes at the site of use. For example, ports, airports, rail yards,and other transportation depots used for shipment of goods requiringfumigation will ordinarily be equipped with container-handling machinery(e.g., cranes, trucks, reach stackers, fork lifts, and straddlecarriers) adapted to accommodate standard-size shipping containers.Moreover, the common presence of damaged or unused shipping containersat such sites provides a ready source of materials for making the stackassembly described herein.

EXAMPLE

The subject matter of this disclosure is now described with reference tothe following Example. This Example is provided for the purpose ofillustration only, and the subject matter is not limited to thisExample, but rather encompasses all variations which are evident as aresult of the teaching provided herein.

A warehouse is fitted with flexible plastic sheets attached to andhanging from the gas-impermeable ceiling thereof. The sheets arearranged in a continuous or overlapping manner so that, when permittedto drape their full length from the ceiling to the floor, they form arectangular enclosure. Materials to be fumigated are moved within theboundary of the rectangular enclosure, and the sheets are drapedcompletely around the materials. Fumigant is generated within the closedstructure and permeate the materials. After a selected fumigation time,the inlet of a first flexible duct is inserted under the plasticsheeting material at one extent of the rectangular structure, and theplastic material is draped over the outside of the duct, so that theinterior of the duct is in fluid communication with the interior of theenclosure. The other end of the duct is connected with the inlet of amanifold which contains a gas conveyor. An outlet of the manifold isfluidly connected, via a second flexible duct, to the inlet end of apipe of the ventilation stack assembly described herein. When the gasconveyor is actuated, it withdraws gas (including fumigant) from withinthe enclosure, conveys it through the first flexible duct, the manifold,the second flexible duct, the pipe and stack of the assembly, and thegas vents out from the stack outlet. Before or after actuating theconveyor, the enclosure is vented (e.g., by fluidly connecting itsinterior with a vent, by lifting a portion of the plastic sheet to allowambient air inflow, or otherwise) to enhance gas flow into and throughthe enclosure. The conveyor remains actuated until a desired degree offumigant removal is achieved, and it is then de-actuated.

The disclosure of every patent, patent application, and publicationcited herein is hereby incorporated herein by reference in its entirety.

While this subject matter has been disclosed with reference to specificembodiments, it is apparent that other embodiments and variations can bedevised by others skilled in the art without departing from the truespirit and scope of the subject matter described herein. The appendedclaims include all such embodiments and equivalent variations.

What is claimed is:
 1. A ventilation stack assembly comprising asubstantially vertical tubular stack having an upper end terminating inan outlet and a lower end; at least one tubular pipe extending from aninlet end to a fitting end, the fitting end being fluidly connected withthe lower end of the stack; and a first housing having the dimensions ofa standard shipping container, having a bottom for resting on asubstantially horizontal surface, and being rigidly connected to atleast one of the stack and the pipe, whereby gas provided to the inletend of the pipe flows through the pipe, into the stack, through thestack, and thence through the outlet of the stack.
 2. The assembly ofclaim 1, wherein the outlet is situated at least about seventy feetabove the substantially horizontal surface.
 3. The assembly of claim 1,wherein first housing is rigidly connected to each of the stack and eachpipe.
 4. The assembly of claim 1, further comprising at least oneadditional housing connected to the top of the first housing, eachadditional housing having the dimensions of the standard shippingcontainer, wherein the stack extends through the top and floor of eachadditional housing.
 5. The assembly of claim 1, wherein the firsthousing is a standard twenty foot intermodal freight container, thestack extends through the top surface of the container, and the pipeextends through one of the opposed smallest faces of the container. 6.The assembly of claim 5, comprising a pair of pipes, each extending atleast about a foot through opposite opposed smallest faces of thecontainer.
 7. The assembly of claim 1, further comprising a ballastcontained within the first housing, the weight of the ballast being atleast about the weight of the stack.
 8. The assembly of claim 1, whereinthe stack has a fitting thereon and a line tautly connects the fittingand the first housing of the assembly.
 9. The assembly of claim 4,wherein the stack has a fitting thereon and a line tautly connects thefitting and a housing of the assembly.
 10. The assembly of claim 9,wherein the line tautly connects the fitting and the uppermost housing.11. The assembly of claim 1, wherein the pipe and the stack areconnected at substantially a right angle.
 12. The assembly of claim 1,wherein the first housing includes connector fittings for a standardshipping container.
 13. The assembly of claim 12, wherein the connectorfittings are twist-lock connector fittings.
 14. The assembly of claim 1,wherein the stack is reversibly attachable to and removable from theassembly.
 15. A method of ventilating a fumigant from an enclosed area,the method comprising fluidly connecting the enclosed area to the inletof the pipe of the assembly of claim 1 and thereafter injecting a fluidinto the enclosed area, whereby the fumigant is displaced from theenclosed area into and through the pipe, into and through the stack, andthence from the outlet.
 16. The method of claim 15, further comprisingsubjecting the gas to incineration between the inlet and the outlet. 17.A ventilation system comprising the ventilation stack assembly of claim1 and a manifold, the manifold comprising a closed body containing a gasconveyor, the body having an outlet fluidly connected with the inlet endof the pipe and at least one intake.
 18. The system of claim 17, whereinthe manifold intake is fluidly connected with an enclosed area.
 19. Aventilation system comprising the ventilation stack assembly of claim 1,an intake line, and a gas conveyor, each fluidly connecting the intakeline with the inlet end of the pipe.
 20. The system of claim 19, whereinan enclosed area is also fluidly connected in line with the gas conveyorand the intake line.